WO2019242906A1

WO2019242906A1 - I3c slave interface, integrated circuit having an i3c slave interface, and method for operating an i3c slave interface

Info

Publication number: WO2019242906A1
Application number: PCT/EP2019/059580
Authority: WO
Inventors: Dorde Cvejanovic; Jan Hayek
Original assignee: Robert Bosch Gmbh
Priority date: 2018-06-21
Filing date: 2019-04-12
Publication date: 2019-12-26
Also published as: DE102018210061A1; US20210019279A1; CN112292673A; US11436180B2

Abstract

The present invention relates to an interface (11) for an I3C slave (1). The interface (11) according to the invention enables I3C slaves (1) to also be connected to a conventional I2C BUS (20) with an I2C master. For this purpose, an additional adaptation device (11, 12) is provided, which adapts the signals of the I2C bus (20) to an l3C slave (1).

Description

description

title

l3C slave interface, integrated circuit with an l3C slave interface and method for operating an l3C slave interface

State of the art

An inter-integrated circuit bus, or I2C-BUS for short, is known as a data bus for communication between different circuit parts, for example between a controller and a peripheral device. This bus system is designed as a master-slave bus system.

The publication DE 10 2012 222 357 A1 discloses an 12C slave interface in which collisions between several devices on the bus are avoided if 12C slave components are operated with different operating modes.

A further development of the l2C bus is the so-called Improved Inter-Integrated Circuit Bus, or I3C-BUS for short. The I3C-BUS is based on the I2C-BUS. In this case, I2C slaves can also be operated on an I3C bus with an I3C master. Mixed operation of l3C slaves and l2C slaves on an I3C bus with an l3C master is also possible. However, a connection of I3C slaves to an I2C bus with an I2C master is not provided.

Disclosure of the invention

The present invention provides an Improved Inter-Integrated Circuit (I3C) slave interface with the features of claim 1, an integrated circuit with the features of claim 6 and a method for operating an I3C slave interface with the features of claim 7.

Accordingly, it is provided: An I3C slave interface for coupling an I3C slave to an I3C bus or an I2C bus. The 13C slave interface includes one

Matching device. The adapter is designed to connect the I3C slave to an I2C bus.

It is also provided:

An integrated circuit with an I3C slave interface according to the invention. Finally, it is provided:

A method of operating an I3C slave interface. The method comprises a step for providing an adaptation device. The adapter is designed to connect an I3C slave to an I2C bus. Furthermore, the method comprises a step for coupling the I3C slave to the adaptation device provided on an I3C bus or an I2C bus.

Advantages of the invention

The present invention is based on the knowledge that although it is possible to operate I2C slaves on an I3C BUS, conversely the operation of I3C slaves on an I2C BUS with an I2C master is not provided.

It is therefore an idea of the present invention to take this knowledge into account and to provide an extension for I3C slaves, which makes it possible to connect an I3C slave interface to an I2C bus. According to the invention, an additional one is used in the 13C slave interface for this purpose

Adaptation device is provided which enables a signal adaptation of the signals between the I2C-BUS and the I3C slave.

Such an adaptation device for adapting the signals of an I2C bus for an I3C slave can be implemented, for example, analogously to a corresponding circuit configuration for coupling an I2C slave to an I2C bus. In particular, such an adaptation device For example, include driver stages, filter elements or delay elements, such as those used for coupling an I2C slave to an I2C bus.

In this way it is also possible to connect 13C slaves to an I2C bus. In particular, it is thus possible to operate new I3C slaves on a conventional I2C bus. In this way, modules with an l3C interface can also be integrated as l3C slaves on existing, conventional infrastructures that are operated with an I2C-BUS, in particular with an l2C master.

On the one hand, this enables the use of modern I3C slaves on conventional, possibly older systems, which have been implemented on the basis of an I2C bus, in particular by means of an I2C master. In addition, l2C bus systems can also be used as bus systems with a larger spatial area, for example due to their lower data rate and their larger tolerances in the signal profiles according to the specifications

Expansion can be operated. By expanding an I3C slave for an I2C bus system according to the invention, it is also possible in such cases to use I3C slaves on a corresponding bus system.

According to one embodiment, the adaptation device for connecting an I3C slave to an I2C bus can be bridged and / or deactivated. In this way, the adapter only has to be integrated into the signal curve between the I3C slave and the connected bus if it is also required for this. This enables, for example, the operation of an I3C slave on I2C bus systems as well as on I3C bus systems.

According to one embodiment, the adaptation device comprises a number of one or more delay elements, glitch filters and / or driver elements. Such circuit elements such as

Delay elements, glitch filters or driver elements are used in particular to connect l2C slaves to an I2C bus. For example, delay elements enable the I2C-BUS to operate, especially in the case of high tolerances, which may be high spatial expansion or other interference, but reliable operation and data exchange. Glitch filters can be used, for example, to debounce the transmitted signals or for similar purposes.

Driver elements, in particular driver elements for the connections to an I2C-BUS, enable adequate signal amplification of the transmitted and / or received signals, in particular the data signals and the clock signals on the I2C-BUS. In addition, of course, any other circuit elements for adapting the signals between an I3C slave and an I2C bus are also possible.

According to one embodiment, the 13C slave interface comprises one

Control device. The control device can be designed to receive external signaling. This external signaling can represent, for example, signaling for the data bus to which the 13C slave interface is or is to be connected. The

Signaling can include, for example, a digital signal, such as a digital voltage signal or the like. In particular, the signaling can be provided, for example, by means of a manual switch. In addition, signaling from a connected further device is also possible. In particular, the signaling

For example, provided once and then in the

Signaling device can be saved. Such signaling thus corresponds, for example, to programming the control device for future operation. In addition, it is also possible that the

Signaling is continuously provided and can be adapted at any later time.

The control device can also be designed to bridge and / or deactivate the adaptation device as a function of the received external signaling. In this way, the operation of the I3C slave interface can be flexibly adapted to a data bus to be connected, in particular to an I2C-BUS or an I3C-BUS.

According to one embodiment, the 13C slave interface comprises one

Detector device. The detector device is designed to detect a connected I3C-BUS or a connected I2C-BUS. The detector device can also be designed to

To bridge or deactivate the adapter if a connected I3C-BUS has been detected. The detection of the

connected bus can be done by any suitable method. For example, the detector device can receive and analyze signals on a connected bus. For example, the type of the connected bus can be identified by means of a detected clock rate, transmitted data or the like. In addition, it is also possible for the detector device to identify the connected bus based on communication with a master of the connected bus. Any other method for detecting the connected bus is of course also possible. In the case of a connected I2C bus, the adaptation device can then be activated or in the

The signal curve can be looped in to adapt the signals between the l3C module and the connected I2C-BUS. If an I3C-BUS has been detected, the adaptation device can be bridged or at least deactivated, so that the signals between the I3C module of the slave and the connected I3C-BUS are no longer modified.

The above refinements and developments can be combined with one another as desired. Further refinements, developments and implementations of the invention also include combinations of previously or hereinafter not explicitly mentioned in relation to the

Features of the invention described embodiments. In particular, the person skilled in the art will also add individual aspects as improvements or additions to the respective basic forms of the invention.

Brief description of the drawings

The present invention is explained in more detail below with reference to the exemplary embodiments given in the schematic figures of the drawings. Show: 1: a schematic representation of a block diagram for an I3C slave with a slave interface according to an embodiment;

2 shows a schematic illustration of a block diagram of an I3C slave with a slave interface according to a further embodiment; and

3: shows a schematic representation of a flowchart as it is based on a method for operating an I3C slave interface according to an embodiment.

Embodiments of the invention

1 shows a schematic illustration of a block diagram of an I3C slave 1 according to one embodiment. The 13C slave 1 can be connected to an I3C-BUS or I2C-BUS 20. The data bus, in particular the I2C bus, can comprise two signal lines 21, 22. One of the two signal lines 21 can be used, for example, as a clock line (SCL = serial clock) and the other line 22 can be used as a data line (SDA = serial data).

The lines 21, 22 of the 12C bus 20 can be connected to a

Adaptation device 11 are coupled. The adaptation device 11 connects the lines 21, 22 of the 12C bus 20 to an internal input / output device 15 of the 13C slave 1. The internal input / output device 15 is designed to receive and transmit signals in a 13C-compliant format , If the I3C slave 1 is connected to an I3C bus with an I3C master, the signals can therefore be directly between the internal input / output device 15 and the I3C bus without further modification

be replaced. In this case, the adaptation device 11 can be bridged or deactivated, for example.

However, if the 13C slave 1 is connected to an I2C bus 20, the adaptation device 11 adapts the signals between the I2C bus 20 and the internal input / output device 15. For example, the signal levels can be adapted using suitable driver elements (not shown) in the adaptation device 11. In this way, the voltage and / or the power provided on the I2C-BUS 20 can be adapted if necessary. In addition, the signals from the I2C-BUS 20 can be debounced, for example, using so-called glitch filters or other suitable circuit elements. Furthermore, it is also possible to delay the rise or fall of an edge in a signal curve on one or both signal lines 21, 22 by means of delay elements in the adaptation device 11. That way

for example, the synchronization of the signal profiles can be adjusted.

In addition, any other suitable circuit elements for adapting the signals between the internal signal profiles according to the I3C standard and the signal profiles on the external I2C bus are also possible.

In this way, by means of the adaptation device 11, a 13C slave 1 can also be connected to an external I2C bus 20 by means of the additional adaptation device 11.

In addition, to allow the most flexible use of the 13C slave 1, the adaptation device 11 can also be bridged and / or deactivated if necessary. In this way, the 13C slave 1 can also be connected to an I3C bus. For example, a

Control device 12 can be provided, which bridges or at least deactivates the adaptation device 11 if necessary. For this purpose, external signaling can be provided on the control device 12, for example. Depending on the external signaling, the control device 12 can then activate or deactivate the adaptation device 11 or also completely bridge the adaptation device 11. For this purpose, signaling can be understood, for example, to apply a predetermined voltage to the control device 12. For this purpose, for example, a mechanical switching element can be switched back and forth between two switching states in order to provide appropriate signaling at the

Provide control device 12. As an alternative, a corresponding signaling on the can also be from a further electronic switching element

Control device 12 can be provided. For example, the control device 12 can store a signaling provided once and then permanently activate, deactivate or bridge the adaptation device 11. Alternatively, it is also possible for the process of activating or deactivating or bridging the adaptation device 11 to be reversible. In this case, the

Control device 12 continuously polls the external signaling and accordingly activates, deactivates or bridges the adaptation device 11.

2 shows a schematic illustration of a block diagram of an I3C slave 1 according to a further embodiment. The 13C slave 1 according to the embodiment in FIG. 2 largely corresponds to the previously described embodiment, so that the corresponding statements have not been repeated here.

The l3C slave 1 according to FIG. 2 differs from the previously described embodiment only in that instead of the control device 12, a detector device 13 is provided, which automatically detects one

connected I2C-BUS 20 detected. In particular, the

Distinguish detector device 13 between a connected I3C-BUS and a connected I2C-BUS 20. If an I2C-BUS has been detected, the adaptation device 11 is activated or looped into the signal flow between the internal input / output device 15 and the I2C-BUS 20. Alternatively, if an I3C-BUS has been detected, the adaptation device 11 is deactivated or bypassed.

The connected bus can be detected by any suitable method. For example, the detector device 13 can analyze the signal profiles on at least one of the lines 21, 22 of the bus in order to infer the respectively connected I3C-BUS or I2C-BUS. In addition, however, any other method for detecting the connected bus is also possible. FIG. 3 shows a schematic illustration of a flowchart as it relates to a method for operating an I3C slave interface according to a

Embodiment is based. First, an adaptation device 11 is provided in step S1. This

Adaptation device 11 is designed to connect an I3C slave 1 to an I2C bus. In step S2, the 13C slave 1 is coupled to the adapter 11 provided on a bus. The I3C slave 1 can either be connected to an I3C bus or an I2C bus.

In particular, the adaptation device 11 can be bridged or deactivated if the 13C slave 1 has been coupled to an I3C bus.

Accordingly, the adaptation device 11 can be activated or in the

Signal path can be looped in if the 13C slave 10 has been coupled to an I2C bus 20.

In summary, the present invention relates to an interface for a 13C slave. The interface according to the invention makes it possible to connect 13C slaves to a conventional I2C bus with an 12C master. For this purpose, an additional adaptation device is provided, which adapts the signals of the 12C bus for an 13C slave.

Claims

Expectations

1. Improved Inter-Integrated Circuit, I3C, slave interface for coupling an I3C slave (1) to an I3C-BUS or an Inter-Integrated Circuit, I2C, bus (20), with: an adapter (11), the is designed to connect the I3C slave (1) to the I2C bus (20).

2. l3C slave interface according to claim 1, wherein the

Adaptation device (11) comprises a number of delay elements, glitch filters and / or driver elements.

3. l3C slave interface according to claim 1 or 2, wherein the

Adaptation device (11) can be bridged or deactivated.

4. l3C slave interface according to one of claims 1 to 3, with a control device (12) which is designed to receive external signaling and to bridge or deactivate the adaptation device (11) depending on the received external signaling ,

5. l3C slave interface according to one of claims 1 to 4, with a detector device (13) which is designed to detect a connected I3C-BUS or a connected I2C-BUS (20), and the adaptation device (11) to bridge or deactivate if a connected I3C-BUS has been detected.

6. Integrated circuit with an I3C slave interface according to one of claims 1 to 5.

7. Method for operating an Improved Inter-Integrated Circuit, I3C, slave interface, with the steps: Providing (S1) an adaptation device (11) which is designed to connect an I3C slave (1) to an Inter-Integrated Circuit , I2C, bus (20); and

Coupling (S2) the l3C slave (1) with the one provided

Adaptation device (11) to an I3C-BUS or an I2C-BUS (20).

8. The method according to claim 7, wherein the adaptation device (11) is bridged or deactivated if the I3C slave (1) is coupled to an I3C bus.